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Highlights of Astronomy, Volume 16 XXVIIIth IAU General Assembly, August 2012 c International Astronomical Union 2015 T. Montmerle, ed. doi:10.1017/S1743921314004657 Very Massive Stars in the local Universe Jorick S. Vink1, Alexander Heger2, Mark R. Krumholz3, Joachim Puls4, S. Banerjee5, N. Castro6,K.-J.Chen7, A.-N. Chen`e8,9, P. A. Crowther10,A.Daminelli11,G.Gr¨afener1,J.H.Groh12, W.-R. Hamann13,S.Heap14, A. Herrero15,L.Kaper16, F. Najarro17, L. M. Oskinova13, A. Roman-Lopes18,A.Rosen3,A.Sander13, M. Shirazi19,Y.Sugawara20,F.Tramper16,D.Vanbeveren21, R. Voss22, A. Wofford23,Y.Zhang24 and the participants of JD2 1 Armagh Observatory, College Hill, BT61 9DG, Armaghm Northern Ireland, UK email: [email protected] 2 Monash Centre for Astrophysics School of Mathematical Sciences, Building 28, M401 Monash University, Vic 3800, Australia 3 Department of Astronomy & Astrophysics, University of California, Santa Cruz, CA 95064, USA 4 Universit¨ats-Sternwarte, Scheinerstrasse 1, 81679, Munchen, Germany 5 Argelander-Institut f¨ur Astronomie, Auf dem H¨ugel 71, D-53121, Bonn, Germany 6 Institute of Astronomy & Astrophysics, National Observatory of Athens, I. Metaxa & Vas. Pavlou St. P. Penteli, 15236 Athens, Greece 7 Minnesota Institute for Astrophysics, University of Minnesota, Minneapolis, MN 55455, USA 8 Departamento de F´ısica y Astronom´ıa, Universidad de Valpara´ıso, Av. Gran Breta˜na 1111, Playa Ancha, Casilla 5030, Chile 9 Departamento de Astronom´ıa, Universidad de Concepci´on, Casilla 160-C, Chile 10Dept. of Physics & Astronomy, Hounsfield Road, University of Sheffield, S3 7RH, UK 11Departamento de Astronomia do IAG-USP, R. do Matao 1226, 05508-090 Sao Paulo, Brazil 12Geneva Observatory, Geneva University, Chemin des Maillettes 51, CH-1290 Sauverny, Switzerland 13Institute for Physics and Astronomy, University Potsdam, 14476 Potsdam, Germany 14NASA Goddard Space Flight Center, Greenbelt, MD 20771, USA 15Instituto de Astrofisica de Canarias and Universidad de La Laguna, E-38200 La Laguna, Spain 16Astronomical Institute ‘Anton Pannekoek’, University of Amsterdam, Science Park 904, PO Box 94249, 1090 GE Amsterdam, The Netherlands 17Departamento de Astrofsica, Centro de Astrobiologia, (CSIC-INTA), Ctra. Torrejn a Ajalvir, km 4, 28850 Torrejon de Ardoz, Madrid, Spain 18Physics Department - Universidad de La Serena - Av. Cisternas, 1200 - La Serena - Chile 19Leiden Observatory, Leiden University, P.O. Box 9513, 2300 RA Leiden, The Netherlands 20Department of Physics, Faculty of Science & Engineering, Chuo University, 1-13-27 Kasuga, Bunkyo, Tokyo 112-8551 21Astrophysical Institute, Vrije Universiteit Brussel, Pleinlaan 2, 1050, Brussels, Belgium 22Department of Astrophysics/IMAPP, Radboud University Nijmegen, PO Box 9010, NL-6500 GL Nijmegen, the Netherlands 23Space Telescope Science Institute, 3700 San Martin Drive, Baltimore, MD, 21218, USA 24Department of Astronomy, University of Florida, Gainesville, FL 32611, USA Abstract. Recent studies have claimed the existence of very massive stars (VMS) up to 300 M in the local Universe. As this finding may represent a paradigm shift for the canonical stellar upper-mass limit of 150 M, it is timely to discuss the status of the data, as well as the far- reaching implications of such objects. We held a Joint Discussion at the General Assembly in Beijing to discuss (i) the determination of the current masses of the most massive stars, (ii) the formation of VMS, (iii) their mass loss, and (iv) their evolution and final fate. The prime aim 51 Downloaded from https://www.cambridge.org/core. Monash University, on 04 Jun 2018 at 04:35:28, subject to the Cambridge Core terms of use, available at https://www.cambridge.org/core/terms. https://doi.org/10.1017/S1743921314004657 52 J. S. Vink et al. was to reach broad consensus between observers and theorists on how to identify and quantify the dominant physical processes. Keywords. Stars: massive stars, Stars: mass-loss, Stars: stellar evolution 1. Introduction The last decade has seen a growing interest in the study of the most massive stars, as their formation seems to be favourable in the early Universe at low metalliciy (Z), and is thought to involve a population of objects in the range 100-300 M (Bromm et al. 1999; Abel et al. 2002). The first couple of stellar generations may be good candidates for the reionization of the Universe. Notwithstanding the role of the first stars, the interest in the current generation of massive stars has grown as well. Massive stars are important drivers for the evolution of galaxies, as the prime contributors to the chemical and energy input into the interstellar medium (ISM) through stellar winds and supernovae (SNe). A number of exciting developments have recently taken place, such as the detection of a long-duration gamma-ray burst (GRB) at a redshift of 9.4, just a few hundred millions years after the Big Bang (Cucchiara et al. 2011). This provides convincing evidence that massive stars are able to form and die massive when the Universe was not yet enriched. The specific reason for holding this JD was the recent evidence for the existence and subsequent deaths of very massive stars (VMS) up to 300 M. Gal-Yam et al. (2009) claimed the detection of a pair-instability SN (PSN) from a VMS. These explosions are thought to disrupt stars without leaving any remnants. Crowther et al. (2010) re- analyzed the most massive hydrogen-and nitrogen-rich Wolf-Rayet (WNh) stars in the center of R136, the ionizing cluster of the Tarantula nebula in the Large Magellanic Cloud (LMC). The conclusion from their analysis was that stars usually assumed to be below the canonical stellar upper-mass limit of 150 M (of e.g. Figer 2005), were actually found to be much more luminous, and with initial masses up to ∼320 M. Prior to discussing the formation, evolution, and fate of VMS, and before we should explore the full implications of these findings, it is imperative to discuss the various lines of evidence for and against VMS. VMS are usually found in and around young massive clusters, such as the Arches cluster in the Galactic centre and the local starburst region R136 in the LMC. Such clusters may harbor intermediate-mass black holes (IMBHs) with masses in the range of several 100 to several 1000 M and may provide insight into the formation of supermassive black holes 5 of order 10 M. Young clusters are also relevant for the unsolved problem of massive star formation. For decades it was a struggle to form stars over 10 M, as radiation pressure on dust grains might halt and reverse the accretion flow onto the central object (e.g., Yorke & Kruegel 1977). Because of this problem, astrophysicists have been creative in forming massive stars via competitive accretion and merging in dense cluster environments (e.g., Bonnell et al. 1998). In more recent times several multi-D simulations have shown that massive stars might form via disk accretion after all (e.g., Krumholz et al. 2009; Kuiper et al. 2010). In the light of recent claims for the existence of VMS in dense clusters, however, we should redress the issue of forming VMS in extreme environments. Massive clusters may be so dense that their early evolution is largely affected by stellar dynamics, and possibly form very massive objects via runaway collisions (e.g., Portegies Zwart et al. 1999; G¨urkan et al. 2004), leading to the formation of VMS up to 1000 M at the cluster center, which may produce IMBHs at the end of their lives, but only if Downloaded from https://www.cambridge.org/core. Monash University, on 04 Jun 2018 at 04:35:28, subject to the Cambridge Core terms of use, available at https://www.cambridge.org/core/terms. https://doi.org/10.1017/S1743921314004657 Very Massive Stars 53 VMS mass loss is not too severe (see Belkus et al. 2007, Yungelson et al. 2008, Glebbeek et al. 2009, Pauldrach et al. 2012). VMS are thought to evolve almost chemically homogeneously (Gr¨afener et al. 2011), implying that knowing the exact details of the mixing processes (e.g., rotation, magnetic fields) could be less relevant in comparison to their canonical ∼10-60 M counterparts. Instead, the evolution and death of VMS is likely dominated by mass loss. A crucial issue regards the relevance of episodes of super-Eddington, continuum-driven mass loss (such as occurs in Eta Carinae and other Luminous Blue Variable (LBV) star eruptions), which might be able to remove large amounts of mass – even in the absence of substantial line-driven winds (see Sect. 6). A final issue concerns the fate of VMS, and more specifically whether VMS end their lives as canonical Wolf-Rayet (WR) stars giving rise to Type Ibc SNe, or do they explode prematurely during the LBV phase? Might some of the most massive stars even produce PSNe? And how do PSNe compare to the general population of super-luminous SNe (SLSNe) that have recently been unveiled by Quimby et al. (2011), and are now seen out to high redshifts (Cooke et al. 2012). Such spectacular events can only be understood once we have obtained a basic knowledge of the physics of VMS. In Section 2 a definition for VMS is adopted, before we discuss the evidence for and against super-canonical stars, i.e. objects above the traditional 150 M stellar upper mass limit (Sect. 3). After it is concluded that VMS probably exist, the next question to address is how to form such objects (Sect. 4). We then discuss the properties of VMS in Sect. 5, before discussing their mass loss (Sect. 6), evolution and fate (Sect. 7). We end with the implications (Sect. 8) and final words. 2. Definition of VMS Before we can discuss the evidences for and against VMS, one of the very first issues we discussed during the JD was what actually constitutes a “very” massive star.
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  • Ngc Catalogue Ngc Catalogue

    Ngc Catalogue Ngc Catalogue

    NGC CATALOGUE NGC CATALOGUE 1 NGC CATALOGUE Object # Common Name Type Constellation Magnitude RA Dec NGC 1 - Galaxy Pegasus 12.9 00:07:16 27:42:32 NGC 2 - Galaxy Pegasus 14.2 00:07:17 27:40:43 NGC 3 - Galaxy Pisces 13.3 00:07:17 08:18:05 NGC 4 - Galaxy Pisces 15.8 00:07:24 08:22:26 NGC 5 - Galaxy Andromeda 13.3 00:07:49 35:21:46 NGC 6 NGC 20 Galaxy Andromeda 13.1 00:09:33 33:18:32 NGC 7 - Galaxy Sculptor 13.9 00:08:21 -29:54:59 NGC 8 - Double Star Pegasus - 00:08:45 23:50:19 NGC 9 - Galaxy Pegasus 13.5 00:08:54 23:49:04 NGC 10 - Galaxy Sculptor 12.5 00:08:34 -33:51:28 NGC 11 - Galaxy Andromeda 13.7 00:08:42 37:26:53 NGC 12 - Galaxy Pisces 13.1 00:08:45 04:36:44 NGC 13 - Galaxy Andromeda 13.2 00:08:48 33:25:59 NGC 14 - Galaxy Pegasus 12.1 00:08:46 15:48:57 NGC 15 - Galaxy Pegasus 13.8 00:09:02 21:37:30 NGC 16 - Galaxy Pegasus 12.0 00:09:04 27:43:48 NGC 17 NGC 34 Galaxy Cetus 14.4 00:11:07 -12:06:28 NGC 18 - Double Star Pegasus - 00:09:23 27:43:56 NGC 19 - Galaxy Andromeda 13.3 00:10:41 32:58:58 NGC 20 See NGC 6 Galaxy Andromeda 13.1 00:09:33 33:18:32 NGC 21 NGC 29 Galaxy Andromeda 12.7 00:10:47 33:21:07 NGC 22 - Galaxy Pegasus 13.6 00:09:48 27:49:58 NGC 23 - Galaxy Pegasus 12.0 00:09:53 25:55:26 NGC 24 - Galaxy Sculptor 11.6 00:09:56 -24:57:52 NGC 25 - Galaxy Phoenix 13.0 00:09:59 -57:01:13 NGC 26 - Galaxy Pegasus 12.9 00:10:26 25:49:56 NGC 27 - Galaxy Andromeda 13.5 00:10:33 28:59:49 NGC 28 - Galaxy Phoenix 13.8 00:10:25 -56:59:20 NGC 29 See NGC 21 Galaxy Andromeda 12.7 00:10:47 33:21:07 NGC 30 - Double Star Pegasus - 00:10:51 21:58:39